KR102649638B1 - Field Magent Unit With Cooling Function - Google Patents

Abstract

The present invention relates to a field unit with a cooling function configured to reduce heat accumulation by providing a refrigerant circulation structure. A field unit with a cooling function according to the present invention includes a housing 10 and a coil member 20 coupled to the housing 10. The housing 10 includes a ring member 11, and an upper plate 12 and a lower plate 13 are coupled to the upper and lower sides of the ring member 11, respectively. The ring member 11, the upper plate 12, and the lower plate 13 are arranged in close contact with the coil member 20, and constitute a magnetic path for the coil member 20. The upper plate 12 and the lower plate 13 are provided with a plurality of flow grooves 122 and 132, respectively, from the outer periphery to the inner direction. The flow grooves 122 and 132 pass through the upper and lower surfaces of the coil member 20, respectively, and then communicate with each other inside the housing 10. The flow grooves 122 and 132 constitute passages for circulation of refrigerant.

Description

Field Magent Unit With Cooling Function}

The present invention relates to a field unit applicable to a power conversion device, and particularly to a field unit with a cooling function configured to reduce heat accumulation by providing a refrigerant circulation structure.

Generally, a field or field unit refers to a magnetic device that generates a magnetic field in an electrical device such as a motor or generator. Typically, magnetic devices are configured such that a coil is wound around a bobbin made of ferrite. As another example of implementing a field unit, one in which a coil is stored inside a cylindrical housing has been proposed. For example, Republic of Korea Patent No. 10-1735860 (title: electromagnet and electromagnetic coil assembly) discloses an electromagnet composed of a flat plate shape. The electromagnet or electromagnetic coil assembly disclosed herein has a structure in which an annular groove is formed in a pole piece made of a magnetizable material, a coil assembly is mounted there, and an armature plate is installed on the upper side.

An example of application of a field unit is a non-rotating power conversion device. Figure 1 is a schematic diagram showing an example of a non-rotating power conversion device. In the drawing, the power conversion device 100 is composed of a field unit 100A and an armature unit 100B in a stacked form. Regarding the power conversion device 100 having this structure, Republic of Korea Patent No. 10-2332747 (name: non-rotating direct current generator), published patent No. 10-2021-0150835 (name: non-rotating alternating current generator), and published patent It is disclosed in No. 10-2021-0161811 (name: Power conversion device).

Generally, a field unit includes a coil member around which a conductive line is wound. The coil member is driven by alternating current or direct current, and is suitably driven by switching. In some applications the coil member is driven at high frequencies. Coil members basically generate heat by resistance loss or eddy current. In particular, when the frequency of the field current or the driving frequency of the coil member increases, heat generation increases dramatically due to an increase in the skin effect and proximity effect. Heat generated from the coil member may accumulate in the coil member. In particular, in the case of a coil member stored inside a housing, excessive heat accumulation may occur. Heat accumulation in the coil member results in an increase in temperature of the conductors constituting the coil member. Additionally, an increase in the temperature of the conductor leads to an increase in its resistance value, further increasing heat generation in the coil member. This inappropriate chain effect not only reduces the magnetic field generation efficiency of the field unit, but can also cause a short circuit in the coil member or a fire.

The present invention was created in consideration of the above circumstances, and its technical purpose is to provide a field unit configured to have a cooling function and prevent excessive heat accumulation in the coil member.

A field unit with a cooling function according to the present invention for realizing the above object is a field unit that generates a magnetic field when a field current is supplied, and includes a housing provided with a hollow portion in the center, and a conductor coated with an insulating material wound thereon. In addition to being configured, it is provided with a terminal for supplying field current, and includes a coil member coupled to the housing, the housing having a hollow ring shape, a ring member on which the coil member is seated, and A top plate is disposed on one side of the ring member, has a disk shape, and has a through hole formed in the central portion to form a hollow portion, and is disposed on the other side of the ring member, has a disk shape, and has a hollow portion in the central portion. It has a lower plate in which a through hole is formed, the upper plate is provided with two or more first flow grooves from the outer periphery to the inner periphery, and the lower plate is provided with two or more second flow grooves from the outer periphery to the inner periphery. , the first flow groove and the second flow groove are characterized in that they communicate with each other inside the housing.

In addition, the sides opposite to the coil members of the upper and lower plates are characterized in that step portions are provided along the outer periphery.

In addition, the upper and lower plates are characterized in that they are press-fitted into the ring member.

In addition, the inner peripheral surface of the ring member is characterized in that a stepped portion for supporting the stepped portion is provided.

Additionally, an insulating film is attached to the outer surface of the upper or lower plate.

In addition, the housing is characterized in that it is made of a material that can be magnetized.

In addition, the field unit with the cooling function has a disk shape, has a through hole formed in the center to form a hollow portion, is seated and installed on the inside of the coil member, and includes a support member for supporting the upper and lower plates. It is characterized in that it is additionally included.

In addition, the diameter of the outer periphery of the support member is set to a size corresponding to the diameter of the inner periphery of the coil member, and the support member is provided with a cut groove from the outer periphery to the inner periphery, and the first flow groove and the second flow groove. 2 The flow grooves are characterized in that they communicate with each other through the cut grooves.

In addition, the height of the ring member is set to a size corresponding to the thickness of the coil member, and the upper and lower plates are arranged in close contact with the coil member and the ring member.

In addition, at least one of the first and second cut grooves is characterized in that it is employed as a guide groove that guides the terminal of the coil member to the outside of the housing.

In addition, the conductive wire constituting the coil member is characterized in that the cross-section is square or has a longitudinal shape.

In addition, the inner peripheral surface of the ring member is characterized in that a guide groove is provided for guiding the outer terminal of the coil member in an upward or downward direction.

Additionally, tubes for circulation of refrigerant are installed in the first and second flow grooves.

According to the present invention having the above-described configuration, the housing is made of a material that can be magnetized, and the coil member is installed in close contact with the housing. Accordingly, the magnetic field generated by the coil member can be projected with high efficiency to other adjacent devices through the housing.

Additionally, a plurality of ducts are provided in the housing while entirely surrounding the outer surface of the coil member. When heat is generated from the coil member, the temperature of the housing and its interior rises due to heat conduction and heat radiation, and thus a flow of air occurs between the inside and outside of the housing. Convection of air occurs through the ducts described above. Additionally, heat energy inside the housing is released to the outside due to the flow of air through the duct, thereby preventing excessive heat energy from accumulating in the housing and coil member.

The attached drawings are for explaining embodiments of the present invention. Therefore, for efficient description of the embodiment, it should be understood that some components may be exaggeratedly described or omitted.
Figure 1 is a configuration diagram schematically showing an example of a power conversion device 100 including a field unit 100A and an armature unit 100B.
Figure 2 is a perspective view showing the external shape of a field unit 1 with a cooling function according to an embodiment of the present invention.
Figure 3 is an exploded perspective view of the field unit 1 shown in Figure 2.
FIG. 4 is a plan view showing the support member 14 disposed on the upper side of the lower plate 13 in FIG. 3.
Figure 5 is a cross-sectional view showing the cross-sectional configuration along line A-A' in Figure 2.

Hereinafter, an embodiment according to the present invention will be described with reference to the drawings. However, the embodiments described below illustratively show one preferred embodiment of the present invention, and the examples of these embodiments are not intended to limit the scope of the present invention. Those skilled in the art will easily understand that the present invention can be implemented with various modifications without departing from its technical spirit.

Figure 2 is a perspective view showing the field unit 1 with a cooling function according to an embodiment of the present invention, and Figure 3 is an exploded perspective view of the field unit 1 shown in Figure 2. In the drawing, the field unit 1 includes a housing 10 and a coil member 20 coupled to the housing 10. The housing 10 includes a ring member 11, an upper plate 12, and a lower plate 13. The ring member 11 constitutes the body of the housing 10. A coil member 20 is stored inside the ring member 14. The upper plate 12 is disposed on one side of the ring member 11, on the upper side of the ring member 11 in the drawing. The lower plate 13 is disposed on the other side of the ring member 11, on the lower side of the ring member 11 in the drawing. The ring member 11, the upper plate 12, and the lower plate 13 accommodate the coil member 20 and form a magnetic path for the coil member 20.

A hollow portion 10a is provided in the central portion of the housing 10. Although not specifically shown in the drawing, a cylindrical core member is inserted into the hollow portion 10a. The field unit 1 is installed and coupled to the core member together with the armature unit. The coupling structure of the field unit and the armature unit to the core member is disclosed in Korean Patent No. 10-2332747 (name: Non-rotating direct current generator).

The upper plate 12 and the lower plate 13 are provided with a plurality of flow grooves 122 and 132, respectively, from the outer periphery to the inner direction. The flow grooves 122 and 132 pass through the upper and lower surfaces of the coil member 20, respectively, and then communicate with each other inside the housing 10. The flow grooves 122 and 132 are for the flow of refrigerant containing air. That is, the flow grooves 122 and 132 constitute ducts for the refrigerant. In addition, at least one of the plurality of flow grooves 122 and 132 functions as a guide groove for leading the terminals 20a and 20b of the coil member 20 to the outside of the housing 10.

3, as described above, the field unit 1 includes a housing 10 and a coil member 20, and the housing 10 includes an upper plate 12, a lower plate 13, and a ring member 14. do. The coil member 20 generates a magnetic field by a field current supplied from the outside, and the housing 10 stably supports and houses the coil member 20 and provides a magnetic field for the magnetic field generated by the coil member 20. It is composed. Furthermore, the housing 10 is provided with a support member 14 . The support member 14 is intended to minimize magnetic flux loss due to the space by eliminating the space between the coil member 20 and the housing. Support member 14 can be removed as needed.

The coil member 20 is composed of a coiled wire coated with an insulating material such as enamel. In addition, preferably, the outside of the coil member 20 may be coated with an insulating film that entirely surrounds the coil member 20 for more reliable insulation between the coil member 20 and the housing 10. The coil member 20 is provided with terminals 20a and 20b for supplying field current. Here, one terminal 20a is connected to the outer peripheral side of the coil member 20, and the other terminal 20b is connected to the inner peripheral side of the coil member 20. As described above, these terminals 20a and 20b are drawn out to the outside of the housing 10 through the cut grooves 122 and 132 of the upper plate 12 and the lower plate 13. Hereinafter, the terminal 20a connected to the outer peripheral side of the coil member 20 will be referred to as an outer terminal, and the terminal 20b connected to the inner peripheral side of the coil member 20 will be referred to as an inner terminal.

Additionally, in a preferred embodiment of the present invention, the coil member 20 is composed of a conductor having a square or rectangular cross-section. A conductor with a square or rectangular cross-section has a larger surface area than a circular conductor with a diameter equal to its width, so it can provide the effect of reducing heat generation due to an increase in the skin effect.

In this embodiment, the upper plate 12 and the lower plate 13 have substantially the same configuration. The lower plate 13 has a disk shape, and a through hole 131 for forming the hollow portion 10a is formed in the central portion. The lower plate 13 is made of a material that can be magnetized. In a preferred embodiment of the present invention, pure iron is adopted as the material of the lower plate 13 and is appropriately heat treated. The heat treatment of the lower plate 13 is to appropriately set the coercive force or demagnetization time of the lower plate 13.

A step portion 133 is provided along the outer periphery of the lower plate 13. Preferably, the outer diameter of the lower plate 13 is set to a size equivalent to the outer diameter of the ring member 11, and the outer diameter of the step portion 133 is set to a size corresponding to the inner diameter of the ring member 11. The step portion 133 is for more stably coupling the lower plate 13 to the ring member 11. In a preferred embodiment of the present invention, the outer diameter of the step portion 133 is set to a size that can be press-fitted into the inner peripheral surface of the ring member 11. The step portion 133 is not essential. This can be removed as needed.

In particular, a plurality of flow grooves 132 are provided on one side of the lower plate 13, that is, on the side opposite to the coil member 20, from the outer periphery to the inner periphery. The flow groove 122 is preferably formed radially. The size and number of flow grooves 132 are not specified. However, the length of the flow groove 132 is set to be larger than the width of the coil member 20.

The upper plate 12, like the lower plate 13, has a disk shape and is made of a material that can be magnetized, and is provided with a through hole 121 and a plurality of flow grooves 122. The flow groove 122 is formed on one side of the upper plate 12, that is, on the side opposite to the coil member 20. In this embodiment, the flow groove 122 is set to have the same shape and position as the flow groove 132 of the lower plate 13. However, the shapes and positions of the flow groove 122 and the flow groove 132 may be set differently. In addition, although not specifically shown in the drawings, a stepped portion is provided on the outer periphery of the upper plate 12 in the same manner as the lower plate 13. The stepped portion of the upper plate 12 has the same shape and function as that of the lower plate 13.

Additionally, in a preferred embodiment of the present invention, an insulating film 12a such as Teflon is attached to the outer surfaces of the upper plate 12 and the lower plate 13. The insulating film 12a is for insulating the main field unit 1 from the armature unit or other field units disposed adjacent to it.

The support member 14 has a disk shape, and a through hole 141 for forming the hollow portion 10a is formed in the central portion. The support member 14, like the upper plate 12 and the lower plate 13, is made of a material that can be magnetized, and is preferably made of heat-treated pure iron. The diameter of the outer periphery of the support member 14 is set to a size corresponding to the diameter of the inner periphery of the coil member 20. The support member 14 is disposed while being seated in the central portion of the coil member 20, and the outer periphery of the support member 14 supports the inner periphery of the coil member 20. Additionally, the thickness of the support member 14 is set to a size corresponding to the thickness of the coil member 20.

In particular, the support member 14 is provided with a plurality of cut grooves 142 from the outer periphery to the inner periphery. Figure 4 is a plan view showing the support member 14 disposed on the upper side of the lower plate 13. As shown in the drawing, the cut groove 142 of the support member 14 is provided at a position corresponding to the flow grooves 122 and 132 provided in the upper plate 12 and the lower plate 13. Accordingly, the flow grooves 122 and 132 communicate with each other through the cut groove 142 of the support member 14. In order to ensure smooth circulation of the refrigerant between the flow grooves 122 and 132, the width of the cut groove 142 is preferably set to be equal or greater than the width of the flow grooves 122 and 132. In addition, although not specifically shown in the drawings, the inner terminal 30b of the coil member 20 is guided upward or downward through the cut groove 142 and then inserted into the housing 10 through the cut grooves 122 and 132. ) is guided to the outside of the

The ring member 11 has a ring shape with a hollow interior. The ring member 11, like the upper plate 12 and the lower plate 13, is made of a material that can be magnetized, and is preferably made of heat-treated pure iron. The diameter of the inner periphery of the ring member 11 is set to a size corresponding to the diameter of the outer periphery of the coil member 20. The coil member 20 is arranged while being seated on the inside of the ring member 11, and the inner periphery of the ring member 11 supports the outer periphery of the coil member 20. Step portions 111 and 112 are provided at the upper and lower ends of the ring member 11, respectively, along the inner peripheral surface. These step portions 111 and 112 are for supporting the step portion 133 of the upper plate 12 and the lower plate 13. The stepped portions 111 and 112 may be removed as needed.

In addition, a guide groove 113 is preferably provided on the inner peripheral surface of the ring member 13 to guide the outer terminal 20a of the coil member 20 in an upward or downward direction. The guide groove 113 is disposed at a position corresponding to the cut grooves 122 and 132 provided in the upper plate 12 and the lower plate 13. Accordingly, the outer terminal 20a of the coil member 20 is guided upward or downward through the guide groove 113 and then guided to the outside of the housing 10 through the cut grooves 122 and 132. The guide groove 113 can be removed when the thickness of the conductor constituting the coil member 20 is below a certain level. The height of the ring member 14 is set to a size corresponding to the thickness of the coil member 20. Accordingly, the support member 14, the coil member 20, and the ring member 11 are arranged while being in close contact with the upper plate 12 and the lower plate 13.

FIG. 5 is a cross-sectional view showing the cross-sectional configuration along line A-A' in FIG. 2. In the drawing, the support member 14 is arranged in close contact with the inner surface of the coil member 20, and the ring member 11 is arranged in close contact with the outer surface of the coil member 20. Additionally, an upper plate 12 and a lower plate 13 are disposed on the upper and lower sides of the coil member 20, respectively, in close contact with each other. The ring member 11, the upper plate 12, the lower plate 13, and the support member 14 constitute the housing 10. Accordingly, the coil member 20 is mounted in close contact with the housing 10. As described above, all components constituting the housing 10 are made of a material that can be magnetized, more preferably a material with high magnetic permeability such as pure iron, and serve as a magnet for projecting the magnetic field generated in the coil member 20. will be provided. Accordingly, the magnetic field generated by the coil member 20 can be efficiently provided to other adjacent devices, such as an armature unit.

In particular, in the housing 10, the flow groove 122 of the upper plate 12, the cut groove 142 of the support member 14, and the flow groove 132 of the lower plate 32 communicate with each other. These communication structures constitute a passage for refrigerant circulation, that is, a duct for refrigerant, for the circulation of refrigerant such as air. The duct for the refrigerant is formed while passing through the upper surface, inner peripheral surface, and lower surface of the coil member 20. That is, the refrigerant duct is configured to allow the refrigerant to flow while entirely surrounding the outer surface of the coil member 20. When the coil member 20 is driven, a large amount of heat is generated from the coil member 20. When heat is generated in the coil member 20, the temperature of the housing 10 and its interior increases due to heat conduction and heat radiation. When the air temperature inside the housing 10 increases, a difference in air density occurs between the inside and outside of the housing 10, and the density difference causes the flow of air, that is, convection, between the inside and outside of the housing 10. It happens. At this time, the flow amount and flow speed of air are proportional to the difference in air density between the inside and outside of the housing 10. In other words, as the temperature inside the housing 10 increases, the flow amount and flow speed of air increase proportionally. Convection of air occurs through a duct for the refrigerant, as shown by the dotted line in the drawing. In addition, heat energy inside the housing 10 is released to the outside by the flow of refrigerant, that is, air, thereby preventing excessive heat energy from accumulating in the housing 10 and the coil member 20.

Above, embodiments according to the present invention have been described. However, the present invention is not limited to the above embodiments. The present invention can be implemented with various modifications without departing from its technical spirit.

For example, in the above-described embodiment, the communication structure consisting of the flow groove 122 of the upper plate 12, the cut groove 142 of the support member 14, and the flow groove 132 of the lower plate 13 contains the refrigerant. Tubes for circulation may be installed.

Additionally, the shape and structure of the support member 14 are not specified. As the support member 14, any structure that can stably support the coil member 20, the upper plate 12, and the lower plate 13 and communicate between the flow grooves 122 and 132 can be preferably employed. there is.

1: field unit, 10: housing,
10a: hollow part, 11: ring member,
12: top plate, 13: bottom plate,
14: support member, 12a: insulating film,
20: coil member, 20a, 20b: terminal.
122, 132: floating groove.

Claims (13)

In the field unit that generates a magnetic field when field current is supplied,
A housing having a hollow portion in the central portion,
It is constructed by winding a conductor coated with an insulating material, has a terminal for supplying field current, and includes a coil member coupled to the housing,
The housing is made of a hollow ring shape, and includes a ring member on the inside of which the coil member is seated,
An upper plate disposed on one side of the ring member and having a disk shape and a through hole formed in the center to form a hollow portion,
A lower plate is disposed on the other side of the ring member, has a disk shape, and has a through hole formed in the center to form a hollow portion,
The top plate is provided with two or more first flow grooves from the outer periphery to the inner periphery,
The lower plate is provided with two or more second flow grooves from the outer periphery to the inner periphery,
A field unit with a cooling function, wherein the first flow groove and the second flow groove communicate with each other inside the housing. According to paragraph 1,
A field unit with a cooling function, characterized in that step portions are provided along the outer periphery on the sides opposite the coil members of the upper and lower plates. According to paragraph 2,
A field unit with a cooling function, wherein the upper and lower plates are press-fitted into the ring member. In paragraph 2
A field unit with a cooling function, characterized in that a step portion for supporting the step portion is provided on the inner peripheral surface of the ring member. According to paragraph 1,
A field unit with a cooling function, characterized in that an insulating film is attached to the outer surface of the upper or lower plate. According to paragraph 1,
A field unit with a cooling function, wherein the housing is made of a material that can be magnetized. According to paragraph 1,
In addition to being in the shape of a disk, a through hole is formed in the central portion to form a hollow portion, is seated and installed on the inside of the coil member, and further includes a support member for supporting the upper and lower plates. Field unit with cooling function. In clause 7,
The diameter of the outer periphery of the support member is set to a size corresponding to the diameter of the inner periphery of the coil member,
The support member is provided with a cut groove from the outer periphery to the inner periphery,
A field unit with a cooling function, wherein the first flow groove and the second flow groove communicate with each other through the cut groove. According to paragraph 1,
A field unit with a cooling function, wherein the height of the ring member is set to a size corresponding to the thickness of the coil member, and the upper and lower plates are arranged in close contact with the coil member and the ring member. According to paragraph 1,
A field unit with a cooling function, wherein at least one of the first and second cut grooves is employed as a guide groove that guides the terminal of the coil member to the outside of the housing. According to paragraph 1,
A field unit with a cooling function, wherein the conductors constituting the coil member have a square or long cross-section. According to paragraph 1,
A field unit with a cooling function, characterized in that a guide groove is provided on the inner peripheral surface of the ring member to guide the outer terminal of the coil member in an upward or downward direction. According to paragraph 1,
A field unit with a cooling function, characterized in that tubes for circulation of refrigerant are installed in the first and second flow grooves.

Images